Japan Geoscience Union Meeting 2023

Presentation information

[E] Online Poster

A (Atmospheric and Hydrospheric Sciences ) » A-HW Hydrology & Water Environment

[A-HW18] Material transportation and cycling at the land-sea interface: from headwaters to the ocean

Thu. May 25, 2023 10:45 AM - 12:15 PM Online Poster Zoom Room (5) (Online Poster)

convener:Takahiro Hosono(Faculty of Advanced Science and Technology, Kumamoto University), Syuhei Ban(The University of Shiga Prefecture), Mitsuyo Saito(Graduate School of Advanced Science and Engineering, Hiroshima University), Adina Paytan(University of California Santa Cruz)


On-site poster schedule(2023/5/26 17:15-18:45)

10:45 AM - 12:15 PM

[AHW18-P19] Evaluation of the practicality of nano-bubble technology for decomposing dissolved hydrogen sulfide in Lake Ogawara

*Fukumoto Yuzuha1, Nagamitsu Maie1, Satoshi Anzai2, Kazunori Shizuka3, Hiroyuki Taruya1 (1.Kitasato University , 2.Anzaikantetsu MCS Division, 3.Inland Water Fishery Research Institute, Aomori Prefectural Industrial Technology Research Center)

Keywords:Brackish Lake, Oxidative decomposition, Hydrogen Sulfide, Nanobubble, Oxygen, Ozone

The ultimate goals of this study are to improve the water quality of eutrophic brackish lakes, recover and resource phosphorus, and establish efficient hydrogen sulfide (H2S) removal technology. Lake Ogawara is a brackish lake in Aomori Prefecture located in the northernmost part of the main island of Japan. There, high concentrations of phosphorus accumulate in a deep high-salinity layer. Therefore, we consider that phosphorus can be efficiently recovered by focusing on this high-salinity layer. However, high concentration of H2S is also present in this layer, hampering phosphorous recovery. H2S is harmful to the human body and corrodes machinery. Accordingly, H2S must be removed before phosphoric acid (PO43-) in the water can be recovered. Therefore, our first goal was set to establish an efficient method for removing H2S from the lake water.
First, as basic information, it is necessary to clarify the amount of H2S in high-salinity water. Therefore, we surveyed a vertical profile of H2S concentration in Lake Ogawara. Water samples were collected every 2 m from the surface to the bottom in the center of Lake Ogawara in Sep. and Nov. 2022, and analyzed for H2S concentration. H2S concentrations were almost 0 mgS/L in the low-salinity layer, but increased to 31–37 mg/L below the halocline layer (12–18 m in Sep, 10–18 m in Nov). Total amount of H2S in the lake water was estimated to be 3.3×103 t in Sep. and 2.8×103 t in Nov., with 83% and 89% of the total distributed in the high-salinity layer, respectively.
Second, the effectiveness of nanobubble (NB) technology for H2S decomposition was evaluated. Specifically, H2S was decomposed using ozone (O3-) NB and oxygen (O2-) NB in a laboratory-scale model experiments. Decomposition rate of H2S concentration due to O3-NB and O2-NB aeration was fitted to the first order reaction equation: y=A0×e-kt+c (A0, initial concentration; k, degradation rate; c, constant). The half-lives of H2S in the decomposition experiments using O2-NB and O3-NB were 20 and 4.0 min, respectively. Based on these results and realistic oxygen supply in the field, it was considered that O3-NB can remove H2S from the high-salinity layer at a practical rate.